A two-stage hybrid ant colony algorithm for multi-depot half-open time-dependent electric vehicle routing problem

IF 5 2区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Lijun Fan
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Abstract

This article presents a detailed investigation into the Multi-Depot Half-Open Time-Dependent Electric Vehicle Routing Problem (MDHOTDEVRP) within the domain of urban distribution, prompted by the growing urgency to mitigate the environmental repercussions of logistics transportation. The study first surmounts the uncertainty in Electric Vehicle (EV) range arising from the dynamic nature of urban traffic networks by establishing a flexible energy consumption estimation strategy. Subsequently, a Mixed-Integer Programming (MIP) model is formulated, aiming to minimize the total distribution costs associated with EV dispatch, vehicle travel, customer service, and charging operations. Given the unique attributes intrinsic to the model, a Two-Stage Hybrid Ant Colony Algorithm (TSHACA) is developed as an effective solution approach. The algorithm leverages enhanced K-means clustering to assign customers to EVs in the first stage and employs an Improved Ant Colony Algorithm (IACA) for optimizing the distribution within each cluster in the second stage. Extensive simulations conducted on various test scenarios corroborate the economic and environmental benefits derived from the MDHOTDEVRP solution and demonstrate the superior performance of the proposed algorithm. The outcomes highlight TSHACA’s capability to efficiently allocate EVs from different depots, optimize vehicle routes, reduce carbon emissions, and minimize urban logistic expenditures. Consequently, this study contributes significantly to the advancement of sustainable urban logistics transportation, offering valuable insights for practitioners and policy-makers.

求解多停车场半开放时变电动汽车路径问题的两阶段混合蚁群算法
由于缓解物流运输对环境影响的紧迫性日益增强,本文对城市配送领域内的多站半开放时间相关电动汽车路线问题(MDHOTDEVRP)进行了详细调查。该研究首先通过建立灵活的能耗估计策略,克服了城市交通网络动态特性所带来的电动汽车续航里程的不确定性。随后,建立了混合整数规划(MIP)模型,旨在最大限度地降低与电动汽车调度、车辆出行、客户服务和充电操作相关的总配送成本。考虑到模型固有的独特属性,提出了一种两阶段混合蚁群算法(TSAACA)作为一种有效的求解方法。该算法在第一阶段利用增强的K-means聚类将客户分配给电动汽车,并在第二阶段采用改进的蚁群算法(IACA)优化每个集群内的分布。在各种测试场景中进行的广泛模拟证实了MDHOTDEVRP解决方案带来的经济和环境效益,并证明了所提出算法的优越性能。结果突出了TSACA从不同仓库高效分配电动汽车、优化车辆路线、减少碳排放和最大限度减少城市物流支出的能力。因此,本研究对促进可持续城市物流运输做出了重大贡献,为从业者和决策者提供了宝贵的见解。
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来源期刊
Complex & Intelligent Systems
Complex & Intelligent Systems COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-
CiteScore
9.60
自引率
10.30%
发文量
297
期刊介绍: Complex & Intelligent Systems aims to provide a forum for presenting and discussing novel approaches, tools and techniques meant for attaining a cross-fertilization between the broad fields of complex systems, computational simulation, and intelligent analytics and visualization. The transdisciplinary research that the journal focuses on will expand the boundaries of our understanding by investigating the principles and processes that underlie many of the most profound problems facing society today.
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